1. bookVolume 11 (2017): Edition 4 (December 2017)
Détails du magazine
Format
Magazine
eISSN
2300-5319
Première parution
22 Jan 2014
Périodicité
4 fois par an
Langues
Anglais
Accès libre

Role of Magnetorheological Fluids and Elastomers in Today’s World

Publié en ligne: 30 Dec 2017
Volume & Edition: Volume 11 (2017) - Edition 4 (December 2017)
Pages: 267 - 274
Reçu: 11 Aug 2016
Accepté: 30 Oct 2017
Détails du magazine
Format
Magazine
eISSN
2300-5319
Première parution
22 Jan 2014
Périodicité
4 fois par an
Langues
Anglais

1. Avraam M.T. (2009): MR-fluid brake design and its application to a portable muscular rehabilitation device, PhD thesis, Active Structures Laboratory Department of Mechanical Engineering and Robotics, Universite Libre de Bruxelles.Search in Google Scholar

2. Bajkowski J. (2004), Modeling, mathematical description, simulation and experimental research of magnetorheological damper with influence of temperature, Machine Dynamic Problems, 28(3), 9-15.Search in Google Scholar

3. Bajkowski J. (2014), Magnetorheological fluids and dampers, Properties, structure, investigations, modeling and applications, Transport and Communication Publishers, Warsaw (in Polish).Search in Google Scholar

4. Bajkowski J., Bajkowski M., Zalewski R. (2007), L’influence de la temperature sur le travail d’un amortiseur magnetorheologique, XV French-Polish Seminar of Mechanics, France.Search in Google Scholar

5. Bajkowski J., Grzesikiewicz W., Holnicki J., Parafiniak M., Wołejsza Z. (2005), Analysis of the influance of magnetorheological damper on the airplane chassis during landing, ECOMAS, Lizbona.Search in Google Scholar

6. Bajkowski M. (2006), Analysis of the influence of selected characteristics of a magnetorheological damper on change of dynamic properties of special object model, PhD dissertation, Warsaw University of Technology, SiMR, Warsaw.Search in Google Scholar

7. Barvosa-Carter W., Johnson N.L., Browne A.L. (2006), Reversibly expandable energy absorbing assembly utilizing actively controlled and engineered materials for impact management and methods for operating the same, US patent 7.140.478 B2.Search in Google Scholar

8. Bazinenkov A., Valery P. Mikhailov V.P. (2004), Active and semi active vibration isolation systems based on magnetorheological materials, Procedia Engineering, 106, 170-174.10.1016/j.proeng.2015.06.021Search in Google Scholar

9. Brei D., Redmond J., Wilmont A.L., Browne N.A., Johnson N.L., Jones G.L. (2006), Hood lift mechanisms utilizing active materials and methods of use, EU patent EP 1 617 022 A2.Search in Google Scholar

10. Carlson J. D. (2001), What makes a good MR fluid?, Proceedings of the Eighth International Conference, Electrorheological Fluids and Magnetorheological Suspensions.10.1142/9789812777546_0010Search in Google Scholar

11. Carlson J.D. (1999), Low-cost MR fluid sponge devices, Proceeding of the 7th international conference on ER fluids and MR suspensions, World Scientific Publishing Co. Pte. Ltd., Honolulu Hawaii.10.1142/9789812793607_0071Search in Google Scholar

12. Carlson J.D., Jolly M.R. (2000), MR fluid, foam and elastomer devices, Mechatronics, 10, 555-569.10.1016/S0957-4158(99)00064-1Search in Google Scholar

13. Carlson J.D., Weiss K.D. (1994), A growing attraction to magnetic fluids, Machine Design, 8, 61-66.Search in Google Scholar

14. Dyke S.J., Spemcer B.F., Sain M.K., Carlson J.D. (1998), An experimental study of MR dampers for seismic protection, Smart Mater Struct., 7, 693-703.10.1088/0964-1726/7/5/012Ouvrir le DOISearch in Google Scholar

15. Dyke S.J., Spencer B.F., Sain M.K., Carlson J.D. (1996), Modeling and control of magnetorheological dampers for seismic response reduction, Smart Materials and Structures, 5(5), 565-575.10.1088/0964-1726/5/5/006Search in Google Scholar

16. Elie L.D., Ginder J.M., Mark J.S., Nichols M.E., Stewart W.M. (1999), Method for allowing rapid evaluation of chassis elastomeric devices in motor vehicles, US patent 5.974.856.Search in Google Scholar

17. Fang F.F., Jang I. B., Choi H.J. (2007), Single-walled carbon nano-tube added carbonyl iron suspension and its magnetorheology, Department of Polymer Science and Engineering, Inha University, In-cheon, 402-751, Republic of Korea.Search in Google Scholar

18. Flores G.A., Liu J. (2002), In-Vitro blockage of a simulated vascular system using magnetorheological fluids as a cancer therapy, European Cells and Materials, 3, 9-11.Search in Google Scholar

19. Forte P., Paternò M., Rustighi E. (2004), A Magnetorheological Fluid Damper for Rotor Applications, International Journal of Rotating Machinery, 10(3), 175-182.10.1155/S1023621X04000181Ouvrir le DOISearch in Google Scholar

20. Genc S. (2002), Synthesis and properties of magnetorheological (MR) fluids, PhD dissertation, University of Pittsburgh.Search in Google Scholar

21. Goncalves F.D. (2005), Characterizing the behavior of magne-torheological fluids at high velocities and high shear rates, PhD thesis, Virginia Polytechnic, Blacksburg.10.1142/9789812702197_0061Search in Google Scholar

22. Gordaninejad F., Sahdi M., Hansen B.C., Chang F.K. (2002), Magneto-rheological fluid dampers for control of bridges, J. of Int. Material Systems and Structures, 13, 167-180.Search in Google Scholar

23. Griffin M.J., Wu X. (1998), The influence of end-stop buffer characteristics on the severity of suspension seat-stop impacts, Journal of sound and vibration, 215(4), 989-996.10.1006/jsvi.1998.1597Search in Google Scholar

24. Hiemenz G., Wereley N. (1999), Seismic response of civil structures utilizing seni-active MR and ER bracing systems, Journal of intelligent material systems and structures, Vol 10, Issue 8, 646-651.10.1106/TTXP-20DM-G861-HU0MSearch in Google Scholar

25. Imthiyaz T.A, Sundarrajan R., Prasaath G.T., Raviraj V. (2014), Implementation of Magneto-rheological Dampers in Bumpers of Automobiles for Reducing Impacts during Accidents, Procedia Engineering, 97, 1220-1226.10.1016/j.proeng.2014.12.400Search in Google Scholar

26. Kaleta J. (2013), Magnetic Materials SMART: Structure, manufacturing, investigations, properties, applications, Publishing House of Wroclaw University of Technology, (in Polish).Search in Google Scholar

27. Kaleta J.Z., Lewandowski D. (2007), Inelastic properties of magnetorheological composites: I. Fabrication, experimental tests, cyclic shear properties, Smart Materials Structures, 16, 1948-1953.10.1088/0964-1726/16/5/052Ouvrir le DOISearch in Google Scholar

28. Kaleta J.Z., Lewandowski D., Ziętek G. (2007), Inelastic properties of magnetorheological composities: II: Model identification of parameters, Smart Materials and Structures, 16, 1954-1960.10.1088/0964-1726/16/5/053Search in Google Scholar

29. Kikuchi T., Ikeda K., Otsuki K., Kakehashi, Furusho J. (2009), Compact MR fluid clutch device for human-friendly actuator, Journal of Physics, 149, 1-4.10.1088/1742-6596/149/1/012059Search in Google Scholar

30. Kikuchi T., Otsuki K., Furusho J., Abe H. (2010), Design and development of compact magnetorheological fluid clutch (CMRFC) with Multi-layered disks and micro-sized gaps, Journal of the Society of Rheology, 38, 17-22.10.1678/rheology.38.17Search in Google Scholar

31. Klukowski C. (2009), Steering column for a motor vehicle, US patent 20090033082 A1.Search in Google Scholar

32. Lee H.G., Sung K.G., Chois S.B. (2009), Ride comfort characteristics with different tire pressure of passenger vehicle featuring MR damper, Journal of Physics, 149, 1-4.10.3741/JKWRA.2009.42.2.149Ouvrir le DOISearch in Google Scholar

33. Lee U., Kim D., Jeon D. (1999), Design analysis and experimental evaluation of an ER and MR clutch, Journal of intelligent materials and structures, Vol 10, Issue 9, pp. 701-707.Search in Google Scholar

34. Li W.H., Zhang X.Z., Du H. (2013), Magnetorheological elastomers and their applications, University of Wollongong, Research Online10.1007/978-3-642-20925-3_12Search in Google Scholar

35. Li Y., Li J., Li W., Du, H. (2014), A state-of-the-art review on magnetorheological elastomer devices, Smart Materials and Structures, 23(12), 1-24.10.1088/0964-1726/23/12/123001Search in Google Scholar

36. Li Z.X., Yu Chen Y., Yun-Dong Shi Y. (2016), Seismic damage control of nonlinear continuous reinforced concrete bridges under extreme earthquakes using MR dampers, Soil Dynamics and Earth-quake Engineering, 88, 386–398.10.1016/j.soildyn.2016.07.015Search in Google Scholar

37. Milecki A. (2001), Investigation and control of magneto-rheological fluid dampers, International journal of machine tools & manufacture, 41, 379-391.10.1016/S0890-6955(00)00085-7Search in Google Scholar

38. Milecki A. (2004), Modeling of magneto-rheological schock absorbers, Archiwum technologii maszyn i automatyzacji (In Polish), Vol 24, no. 2, 123-129.Search in Google Scholar

39. Milecki A., Ławniczak A. (1999), Electro- and Magnetorheological fluids and their applications in technics, Publishing house of Poznan University of Technology (in Polish).Search in Google Scholar

40. Muc A., Barski M. (2007), Magnetorheological fluids and their practical applications, Publishing house of Cracow University of Technology (in Polish).Search in Google Scholar

41. Nyawako D., Reynolds P. (2007), Technologies for mitigation of human – induced vibrations in civil engineering structures, The shock and vibration digest, 39(6), 465-493.10.1177/0583102407084286Search in Google Scholar

42. Olabi A. G., Grunwald A. (2007), Design and application of magneto-rheological fluid, Materials and Design, 28, 2658-2664.10.1016/j.matdes.2006.10.009Search in Google Scholar

43. Ottaviani R.A., Ulicny J.C., Golden M.A. (2006), Magnetorheological nanocomposite elastomer for releasable attachment applications, US patent 6.877.193 B2.Search in Google Scholar

44. Park Ch., Jeon D. (2002), Semiactive vibration control of a smart seat with an MR fluid damper considering its time delay, Journal of intelligent material systems and structures, 13, 521-524.10.1106/104538902030343Search in Google Scholar

45. Park E. J., Falcao L., Suleman A. (2008), Multidisciplinary design optimization of an automotive magnetorheological brake design, Computers and Structures, 86, 207-216.10.1016/j.compstruc.2007.01.035Search in Google Scholar

46. Poynor J. C. (2001), Innovative Designs for Magneto-Rheological Dampers, master thesis, Virginia Polytechnic, Blacksburg.Search in Google Scholar

47. Rabinow J. (1948), The magnetic fluid clutch, AIEE Transactions, 67: 1308-1315.10.1109/T-AIEE.1948.5059821Search in Google Scholar

48. Rabinow J. (1951), Magnetic fluid torque and force transmitting device, U.S. Patent 2, 575.Search in Google Scholar

49. Sapiński B. (2006), Magnetorheological dampers in vibration control, AGH University of Science and Technology Press, KrakówSearch in Google Scholar

50. Sapiński B., Snamina J. (2007), Cable – MR damper system motion in transients, Mechanics 26, 22-29.Search in Google Scholar

51. Sapiński B., Snamina J., Maślanka M, Rosół M. (2006), Facility for testing of magnetorheological damping systems for cable vibrations, Mechnics, 25/3, 135-Search in Google Scholar

52. Sassi S., Cherif K., Mezghani L., Thomas M., Kotrante A. (2005), An innovative magnetorheological damper for automotive suspension: from design to experimental characterization, Smart Mater. Struct., 14, 811-822.10.1088/0964-1726/14/4/041Ouvrir le DOISearch in Google Scholar

53. Schwartz M. (2009), Smart Materials, Taylor and Francis GroupSearch in Google Scholar

54. Skalski P (2014), Morphing Structure with a Magnetorheological Material – Preliminary Approach, Mechatronics 2013 Recent Technological and Scientific Advanced. Springer International Publishing, 219-226.Search in Google Scholar

55. Skalski P., Parafiniak M., Wysokiński D., Bednarski M. (2014), Aerodynamic profile with elastic skin of active material, P-409202, Polish patent, 29.02.2016.Search in Google Scholar

56. Skorupka Z. (2010), Magnetorheological fluids as method for active controlling of landing gear shock absorber characteristic, Transactions of the Institute of Aviation, 207, 36-48.Search in Google Scholar

57. Spaggiari A. (2013), Properties and applications of Magnetorheological fluids, Dept. of Engineering Sciences and Methods, University of Modena and Reggio Emilia, Italy.Search in Google Scholar

58. Spencer B. F., Tomizuka M., Yun C. B., Chen W. M., Chen R. W. (2007) World Forum on Smart Materials and Smart Structures Technology, Proceedings of the World Forum on Smart Materials and Smart Structures Technology, Taylor & Francis Group, 291-294.10.1201/9781439828441Search in Google Scholar

59. Stewart W.M., Ginder J.M., Ellie L.D., Nicholas M.E. (1998), Method and apparatus for reducing brake shudder, US patent 5.816.587.Search in Google Scholar

60. Szeląg W., Nowak L., Myszkowski A. (2000), Electromagnetic brake with magnetorheological fluid, Scientific Works of the Institute of Electric Machines, Drives and Measurements, 48, 206-213.Search in Google Scholar

61. Tao R. (2011), Electro-Rheological Fluids And Magneto-Rheological Suspensions, Proceedings of the 12th International Conference, World Scientific, Singapure, 748.Search in Google Scholar

62. Thorarinsson E. T., Jonsdottir F., Palsson H. (2006), Design of a Magnetorheological Prosthetic Knee, Department of Mechanical Engineering, University of Iceland.Search in Google Scholar

63. Watson J.R. (1997), Method and apparatus for varying the stiffness of a suspension busing, US patent 5.609.353.Search in Google Scholar

64. Xiao-min D., Yu Miao, Liao C., Chen W. (2009), A new variable stiffness absorber based on magneto-rheological elastomer, Transactions of Nonferrous Metals Society of China, 19, 611-615.10.1016/S1003-6326(10)60118-5Ouvrir le DOISearch in Google Scholar

65. Yoon S.-S., Kang S., Kim S.J., Kim Y.-H., Kim M., Lee C. (2003), Safe arm with MR-based passive compliant joints and visco-elastic covering for service robot applications, Intl. Conference on Intelligent Robots and Systems, October, Nevada, 2191-2196.Search in Google Scholar

66. BWI Group.com, MAGNERIDE™ CONTROLLED SUSPENSION SYSTEM (2013), http://www.bwigroup.com/en/pshow.php?pid=22; 08.08.2016.Search in Google Scholar

67. BWI Group.com, MAGNETO-RHEOLOGICAL MOUNTS (2013) http://www.bwigroup.com/en/pshow.php?pid=26; 08.08.2016.Search in Google Scholar

68. Carlson J.D. (2002), http://www.sensorsmag.com/sensors/electric-magnetic/controlling-vibration-with-magnetorheological-fluid-damping-999; 08.08.2016.Search in Google Scholar

69. http://robohub.org/icelands-ossur-wins-popsci-best-of-whats-new-award-for-symbionic-leg/; 08.08.2016.Search in Google Scholar

70. https://www.dywidag-systems.com/emea/projects/project-details/article/dr-franjo-tudjmann-bridge-dubrovnik-croatia.html; 08.08.2016.Search in Google Scholar

71. Magneto-Rheological (MR) Fluid, “LORD is proud to be the exclusive supplier of MR Fluid technology…” Retrieved from: http://www.lord.com/products-and-solutions/active-vibration-control/industrial-suspension-systems/magneto-rheological-(mr)-fluid; 08.08.2016.Search in Google Scholar

Articles recommandés par Trend MD

Planifiez votre conférence à distance avec Sciendo